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Transcript
Advanced Databases
Lecture 6- Query Optimization
(continued)
Masood Niazi Torshiz
Islamic Azad university- Mashhad Branch
www.mniazi.ir
Materialized Views**
n
A materialized view is a view whose contents are computed and
stored.
n
Consider the view
create view department_total_salary(dept_name, total_salary) as
select dept_name, sum(salary)
from instructor
group by dept_name
n
Materializing the above view would be very useful if the total salary by
department is required frequently
l
Saves the effort of finding multiple tuples and adding up their
amounts
Database System Concepts - 6th Edition
1.2
©Silberschatz, Korth and Sudarshan
Materialized View Maintenance
n
The task of keeping a materialized view up-to-date with the underlying
data is known as materialized view maintenance
n
Materialized views can be maintained by recomputation on every
update
n
A better option is to use incremental view maintenance
l
n
Changes to database relations are used to compute changes
to the materialized view, which is then updated
View maintenance can be done by
l
Manually defining triggers on insert, delete, and update of each
relation in the view definition
l
l
Manually written code to update the view whenever database
relations are updated
Periodic recomputation (e.g. nightly)
l
Above methods are directly supported by many database systems

Avoids manual effort/correctness issues
Database System Concepts - 6th Edition
1.3
©Silberschatz, Korth and Sudarshan
Incremental View Maintenance
n
The changes (inserts and deletes) to a relation or expressions are
referred to as its differential
l
n
Set of tuples inserted to and deleted from r are denoted ir and dr
To simplify our description, we only consider inserts and deletes
l
We replace updates to a tuple by deletion of the tuple followed by
insertion of the update tuple
n
We describe how to compute the change to the result of each
relational operation, given changes to its inputs
n
We then outline how to handle relational algebra expressions
Database System Concepts - 6th Edition
1.4
©Silberschatz, Korth and Sudarshan
Join Operation
n
Consider the materialized view v = r
s and an update to r
n
Let rold and rnew denote the old and new states of relation r
n
Consider the case of an insert to r:
s as (rold  ir)
l
We can write rnew
l
And rewrite the above to (rold
l
But (rold s) is simply the old value of the materialized view, so
the incremental change to the view is just
ir s
Thus, for inserts
n
Similarly for deletes
A, 1
B, 2
C,2
s)  (ir
vnew = vold (ir
n
s
s)
s)
vnew = vold – (dr
s)
A, 1, p
B, 2, r
B, 2, s
1, p
2, r
2, s
C, 2, r
C, 2, s
Database System Concepts - 6th Edition
1.5
©Silberschatz, Korth and Sudarshan
Selection and Projection Operations
n
Selection: Consider a view v = (r).
l vnew = vold (ir)
l vnew = vold - (dr)
Projection is a more difficult operation
l R = (A,B), and r(R) = { (a,2), (a,3)}
l
A(r) has a single tuple (a).
l If we delete the tuple (a,2) from r, we should not delete the tuple (a)
from A(r), but if we then delete (a,3) as well, we should delete the
tuple
n For each tuple in a projection A(r) , we will keep a count of how many
times it was derived
l On insert of a tuple to r, if the resultant tuple is already in A(r) we
increment its count, else we add a new tuple with count = 1
n
l
On delete of a tuple from r, we decrement the count of the
corresponding tuple in A(r)
 if the count becomes 0, we delete the tuple from A(r)
Database System Concepts - 6th Edition
1.6
©Silberschatz, Korth and Sudarshan
Aggregation Operations
n
count : v = Agcount(B)(r).
l
When a set of tuples ir is inserted

l
For each tuple r in ir, if the corresponding group is already present in v,
we increment its count, else we add a new tuple with count = 1
When a set of tuples dr is deleted

for each tuple t in ir.we look for the group t.A in v, and subtract 1 from
the count for the group.
– If the count becomes 0, we delete from v the tuple for the group t.A
n
sum: v = Agsum (B)(r)
l
We maintain the sum in a manner similar to count, except we add/subtract
the B value instead of adding/subtracting 1 for the count
l
Additionally we maintain the count in order to detect groups with no tuples.
Such groups are deleted from v

n
Cannot simply test for sum = 0 (why?)
To handle the case of avg, we maintain the sum and count
aggregate values separately, and divide at the end
Database System Concepts - 6th Edition
1.7
©Silberschatz, Korth and Sudarshan
Aggregate Operations (Cont.)
n
min, max: v = Agmin (B) (r).
l
Handling insertions on r is straightforward.
l
Maintaining the aggregate values min and max on deletions may
be more expensive. We have to look at the other tuples of r that
are in the same group to find the new minimum
Database System Concepts - 6th Edition
1.8
©Silberschatz, Korth and Sudarshan
Other Operations
n
n
Set intersection: v = r  s
l
when a tuple is inserted in r we check if it is present in s, and if so
we add it to v.
l
If the tuple is deleted from r, we delete it from the intersection if it
is present.
l
Updates to s are symmetric
l
The other set operations, union and set difference are handled in
a similar fashion.
Outer joins are handled in much the same way as joins but with some
extra work
l
we leave details to you.
Database System Concepts - 6th Edition
1.9
©Silberschatz, Korth and Sudarshan
Handling Expressions
n
To handle an entire expression, we derive expressions for computing
the incremental change to the result of each sub-expressions, starting
from the smallest sub-expressions.
n
E.g. consider E1
expression
l
Suppose the set of tuples to be inserted into E1 is given by D1

l
E2 where each of E1 and E2 may be a complex
Computed earlier, since smaller sub-expressions are handled
first
Then the set of tuples to be inserted into E1
D1 E2

E2 is given by
This is just the usual way of maintaining joins
Database System Concepts - 6th Edition
1.10
©Silberschatz, Korth and Sudarshan
Query Optimization and Materialized Views
n
Rewriting queries to use materialized views:
l
A materialized view v = r
l
A user submits a query
l
We can rewrite the query as v

n
n
s is available
r
s
t
t
Whether to do so depends on cost estimates for the two alternative
Replacing a use of a materialized view by the view definition:
l
A materialized view v = r
s is available, but without any index on it
l
User submits a query A=10(v).
l
Suppose also that s has an index on the common attribute B, and r has
an index on attribute A.
l
The best plan for this query may be to replace v by r
lead to the query plan A=10(r)
s
s, which can
Query optimizer should be extended to consider all above
alternatives and choose the best overall plan
Database System Concepts - 6th Edition
1.11
©Silberschatz, Korth and Sudarshan
Materialized View Selection
n
Materialized view selection: “What is the best set of views to
materialize?”.
n
Index selection: “what is the best set of indices to create”
l
n
closely related, to materialized view selection
 but simpler
Materialized view selection and index selection based on typical
system workload (queries and updates)
l
Typical goal: minimize time to execute workload , subject to
constraints on space and time taken for some critical
queries/updates
l
One of the steps in database tuning

n
more on tuning in later chapters
Commercial database systems provide tools (called “tuning
assistants” or “wizards”) to help the database administrator choose
what indices and materialized views to create
Database System Concepts - 6th Edition
1.12
©Silberschatz, Korth and Sudarshan
Top-K Queries
n
Top-K queries
select *
from r, s
where r.B = s.B
order by r.A ascending
limit 10
l
Alternative 1: Indexed nested loops join with r as outer
l
Alternative 2: estimate highest r.A value in result and add
selection (and r.A <= H) to where clause

If < 10 results, retry with larger H
Database System Concepts - 6th Edition
1.13
©Silberschatz, Korth and Sudarshan
Optimization of Updates
n
Halloween problem
update R set A = 5 * A
where A > 10
l
If index on A is used to find tuples satisfying A > 10, and tuples
updated immediately, same tuple may be found (and updated)
multiple times
l
Solution 1: Always defer updates
l

collect the updates (old and new values of tuples) and update
relation and indices in second pass

Drawback: extra overhead even if e.g. update is only on R.B,
not on attributes in selection condition
Solution 2: Defer only if required

Perform immediate update if update does not affect attributes
in where clause, and deferred updates otherwise.
Database System Concepts - 6th Edition
1.14
©Silberschatz, Korth and Sudarshan
Join Minimization
n Join minimization
select r.A, r.B
from r, s
where r.B = s.B
n Check if join with s is redundant, drop it
l
E.g. join condition is on foreign key from r to s, r.B is declared
as not null, and no selection on s
l
Other sufficient conditions possible
select r.A, s2.B
from r, s as s1, s as s2
where r.B=s1.B and r.B = s2.B and s1.A < 20 and s2.A < 10
 join
with s1 is redundant and can be dropped (along with
selection on s1)
l
Lots of research in this area since 70s/80s!
Database System Concepts - 6th Edition
1.15
©Silberschatz, Korth and Sudarshan
Multiquery Optimization
n Example
Q1: select * from (r natural join t) natural join s
Q2: select * from (r natural join u) natural join s
l
Both queries share common subexpression (r natural join s)
l
May be useful to compute (r natural join s) once and use it
in both queries
 But
this may be more expensive in some situations
– e.g. (r natural join s) may be expensive, plans as
shown in queries may be cheaper
n Multiquery optimization: find best overall plan for a set of
queries, expoiting sharing of common subexpressions between
queries where it is useful
Database System Concepts - 6th Edition
1.16
©Silberschatz, Korth and Sudarshan
Multiquery Optimization (Cont.)
n Simple heuristic used in some database systems:
l
optimize each query separately
l
detect and exploiting common subexpressions in the
individual optimal query plans
 May
l
not always give best plan, but is cheap to implement
Shared scans: widely used special case of multiquery
optimization
n Set of materialized views may share common subexpressions
l
As a result, view maintenance plans may share
subexpressions
l
Multiquery optimization can be useful in such situations
Database System Concepts - 6th Edition
1.17
©Silberschatz, Korth and Sudarshan
Parametric Query Optimization
n
Example
select *
from r natural join s
where r.a < $1
l
value of parameter $1 not known at compile time

l
n
different plans may be optimal for different values of $1
Solution 1: optimize at run time, each time query is submitted

n
can be expensive
Solution 2: Parametric Query Optimization:
l
l
n
known only at run time
optimizer generates a set of plans, optimal for different values of $1

Set of optimal plans usually small for 1 to 3 parameters

Key issue: how to do find set of optimal plans efficiently
best one from this set is chosen at run time when $1 is known
Solution 3: Query Plan Caching
l
If optimizer decides that same plan is likely to be optimal for all parameter
values, it caches plan and reuses it, else reoptimize each time
l
Implemented in many database systems
Database System Concepts - 6th Edition
1.18
©Silberschatz, Korth and Sudarshan
Extra Slides
(Not in 6th Edition book)
Database System Concepts - 6th Edition
1.19
©Silberschatz, Korth and Sudarshan
Plan Stability Across Optimizer Changes
n
What if 95% of plans are faster on database/optimizer version N+1
than on N, but 5% are slower?
l
Why should plans be slower on new improved optimizer?

n
Answer: Two wrongs can make a right, fixing one wrong can
make things worse!
Approaches:
l
Allow hints for tuning queries

l
Set optimization level, default to version N (Oracle)

l
Not practical for migrating large systems with no access to
source code
And migrate one query at a time after testing both plans on
new optimizer
Save plan from version N, and give it to optimizer version N+1

Sybase, XML representation of plans (SQL Server)
Database System Concepts - 6th Edition
1.20
©Silberschatz, Korth and Sudarshan